Transgenic soybean plants and chromosomes

ABSTRACT

Described herein are transgenic soybean chromosomes containing a recombinant DNA that transcribes to an RNA molecule that hybridizes to and forms a cleavage-resistant duplex with either a mature miR171 miRNA or a transcript of a target gene having a recognition site for a mature miR171 miRNA whereby the function of the miR171 miRNA is inhibited and thereby imparts enhanced agronomic traits to soybean plants such as increased pods per node, increased number of nodes, a decreased distance between nodes, and a twisted stem.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of co-pending U.S. patent applicationSer. No. 13/502,737, filed Jul. 2, 2012, which is a 371 National StageApplication of PCT/US2009/68754, filed Dec. 18, 2009, which claims thepriority of U.S. Provisional Application Ser. No. 61/254,555, filed Oct.23, 2009, which are herein incorporated by reference in its entirety.

INCORPORATION OF SEQUENCE LISTINGS

The sequence listing that is contained in the file named“38-21-56969BPCT.txt”, which is 26.3 kilobytes as measured in MicrosoftWindows operating system and was created on 11 Dec. 2009, is filedelectronically herewith and incorporated herein by reference.

FIELD OF THE INVENTION

Disclosed herein are transgenic chromosomes that contain a DNA constructthat is transcribed to an RNA molecule in soybean plant cells to provideenhanced agronomic traits in such soybean plants and seeds for suchplants and raw materials produced from such plants, and methods ofmaking and using such molecules, chromosomes, cells, plants, seeds andraw materials.

SUMMARY OF THE INVENTION

This invention provides a non-natural transgenic chromosome in a soybeanplant cell that includes a recombinant DNA construct that is transcribedto an RNA molecule that hybridizes under physiological conditions to andforms a cleavage-resistant duplex with a mature miR171miRNA or atranscript of a miR171-associated miRNA target gene having a recognitionsite for a mature miR171 miRNA. Such a cleavage-resistant duplexinhibits the function of at least one mature miR171 miRNA in a soybeancell. The non-natural transgenic chromosome of this invention isprovided in a soybean plant cell in a non-natural, transgenic soybeanplant having enhanced agronomic characteristics selected from a groupconsisting of increased pods per node, increased number of internodesand nodes, decreased average internode length, and a twisted stemphenotype as compared to a control.

The RNA molecule of this invention that hybridizes to a mature miR171miRNA or its corresponding, complementary recognition site is designedwith reference to a miR171 miRNA consensus sequence ofUGAUUGAGCCGCGCCAAUAUC (SEQ ID NO: 91), with up to 6 mismatches and wherethe underlined nucleotide pair CG at positions 10 and 11 spans thenominal cleavage site, or of UUGAGCCGNGCCAAUAUCACN (SEQ ID NO: 92) withup to 6 mismatches and where the underlined nucleotide pair at GC atpositions 10 and 11 spans the nominal cleavage site. The actual maturemiR171 miRNA can have a deletion or an addition at either the 5′ or 3′end. Specific miR171 miRNAs have a nucleotide sequence selected from thegroup consisting of SEQ ID NO: 17 through SEQ ID NO: 90.

In a broad aspect of the invention the non-natural transgenic chromosomehas DNA that is transcribed to an RNA molecule that hybridizes to amature miR171 miRNA to form a cleavage-resistant duplex between the RNAmolecule and the miR171 miRNA where the cleavage site of the maturemiR171 miRNA is between nucleotides that correspond to the nucleotidesat positions 10 and 11 of the one of the above consensus RNA nucleotidesequences that best aligns with the nucleotide RNA sequence of thetargeted mature miR171 miRNA. The RNA molecule of this invention has atleast one nucleotide mismatch with the mature miR171 miRNA or itscorresponding recognition site generally at positions 9-12 at thecleavage site of the mature miR171 miRNA. For instance, the RNA moleculedesigned to hybridize to a mature miR171 miRNA is not perfectly basepaired with the mature miR171 miRNA (a) at least at position 11 at thecleavage site of the mature miR171 miRNA, or (b) at least at positions10 and 11 at the cleavage site of the mature miR171 miRNA, or (c)includes at least one insertion nucleotide between nucleotides that arecomplementary to positions 10 and 11 at the cleavage site of the maturemiR171 miRNA. An effective RNA molecule of this invention thathybridizes to a mature miR171 miRNA has at least three insertionnucleotides between the nucleotides of the RNA molecule that arecomplementary to positions 10 and 11 at the cleavage site of the maturemiR171 miRNA. Useful transcribed RNA molecules of the invention have anucleotide sequence of any of SEQ ID NO: 93 through SEQ ID NO: 118.

An RNA molecule transcribed from a recombinant DNA construct of thisinvention inhibits double-stranded RNA-mediated suppression of at leastone mature miR171 miRNA. Such RNA molecules are provided in anon-natural soybean plant cell having a non-natural transgenicchromosome with a recombinant DNA construct.

In various other aspects, this invention provides a cleavage-resistantduplex between a transcribed RNA molecule and a mature miR171 miRNA. Acleavage-resistant duplex formed by a hybridized RNA molecule of thisinvention increases the expression of the miR171 miRNA target generelative to expression in the absence of the RNA molecule. Such acleavage-resistant duplex includes at least 6 base pairs or at least 10base pairs in the recognition site of the mature miR171 miRNA. Thecleavage-resistant duplex includes at least one mismatch at the cleavagesite corresponding to positions 9, 10, 11 or 12 within the mature miR171miRNA, or at least one insertion at a position in the RNA molecule andsaid recognition site corresponding to positions 10-12 within the maturemiR171 miRNA, or a mismatch at a position corresponding to the 3′ end ofthe recognition site. Examples of useful transcribed RNA molecules ofthe invention include those with a nucleotide sequence of any of thesequences of SEQ ID NO: 119 through SEQ ID NO: 143.

In yet a further aspect, a non-natural transgenic chromosome of thisinvention is contained in a non-natural transgenic soybean cell, in alive soybean plant, in a dead soybean plant, in a soybean seed, or in anindustrial raw material, i.e., processed soybean seed.

In another aspect this invention provides a dead non-natural transgenicsoybean plant that has increased pods per node as compared to thecontrol, where the pods contain soybean seeds including a non-naturaltransgenic chromosome of this invention.

In a further aspect this invention provides a method of increasing thenumber of pods per node, or of increasing the number of internodes andnodes per plant, or of decreasing the distance between internodes, or ofimparting a twisted stem phenotype in a soybean plant, as compared to acontrol, by providing in cells of the soybean a non-natural transgenicchromosome of this invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1B illustrates structures of transcribed RNA molecules thathybridize to a mature miR171 miRNA to form a cleavage-resistant duplexwith a three-nucleotide insertion (labelled “bulge”) corresponding topositions 10-11 cleavage site of the miR171 miRNA (FIG. 1A) or with twomismatches (labelled “mismatch”) corresponding to positions 10 and 11 ofthe cleavage site of the miR171 miRNA (FIG. 1B).

FIG. 2 is a photograph illustrating characteristics of a non-naturaltransgenic soybean plant having a chromosome of the invention relativeto a control plant.

FIGS. 3A-3B are photographs illustrating characteristics of anon-natural transgenic soybean plant having a chromosome of theinvention that imparts an increased pods per node phenotype (FIG. 3A)and a twisted stem phenotype (FIG. 3B).

FIGS. 4A-4B graphically illustrates characteristics of a non-naturaltransgenic soybean plant having a chromosome of the invention thatimparts a decreased internode length (FIG. 4A) and an increased podnumber (FIG. 4B) compared to a non-transgenic control plant.

DETAILED DESCRIPTION OF THE INVENTION

This invention provides a non-natural transgenic chromosome in a soybeanplant cell, wherein the non-natural transgenic chromosome has arecombinant DNA construct including DNA that is transcribed to an RNAmolecule that under physiological conditions in a soybean plant cellhybridizes to and forms a cleavage-resistant duplex with either a maturemiR171 miRNA or a transcript of a target gene having a recognition sitefor a mature miR171 miRNA, wherein the recognition site includesnucleotides complementary to nucleotides of the mature miR171 miRNA,whereby the function of the mature miR171 mRNA is inhibited in thesoybean plant cell, and wherein the soybean plant cell is in anon-natural, transgenic soybean plant having enhanced agronomiccharacteristics selected from a group consisting of increased pods pernode, increased number of internodes and nodes, decreased averageinternode length, and a twisted stem phenotype as compared to a control.The RNA molecule that hybridizes under physiological conditions in asoybean plant cell to form a cleavage-resistant RNA duplex with either amature miR171 miRNA or a transcript of a target gene having arecognition site for a mature miR171 miRNA reduces the function of themature miR171 miRNA. The non-natural transgenic chromosomes and therecombinant DNA constructs contained therein are useful for making anon-natural, transgenic soybean plant having enhanced agronomiccharacteristics selected from a group consisting of increased pods pernode, increased number of internodes and nodes, decreased averageinternode length, and a twisted stem phenotype, as compared to acontrol.

The physiological conditions for the hybridizing in the practice of thisinvention are common field conditions during the growing season of asoybean plant. For example, the RNA molecule of this inventionhybridizes to and forms a cleavage-resistant duplex with a mature miR171miRNA in a cell of a soybean plant growing in a field under conditionsincluding temperatures between about 20 to about 30 degrees Celsius andat a relative humidity between about 50 to about 100 percent.

A “control” generally means a plant that does not contain thenon-natural transgenic chromosomes containing the recombinant DNAconstruct that transcribes to an RNA molecule of this invention thathybridizes under physiological conditions in a soybean cell to a maturemiR171 miRNA or a transcript of a target gene having a recognition sitefor a mature miR171 miRNA to form a cleavage-resistant. A control can bea wild-type non-transgenic plant corresponding to the non-naturaltransgenic variety that contains the chromosome or recombinant DNAconstruct of the invention. A control can be a null variant progeny of ahomozygous transgenic parent plant having the chromosome or recombinantDNA of the invention. A suitable control plant can be a non-transgenicplant of the parental line used to generate a transgenic plant, e. g.,devoid of recombinant DNA and can in some cases is a progeny of ahemizygous transgenic plant line that does not contain the recombinantDNA, known as a negative segregant or negative isoline. In someembodiments, a control is a plant that contains a recombinant DNAconstruct encoding an RNA molecule of this invention, but where therecombinant DNA construct is not transcribed. A control is useful toidentify and select a transgenic plant of this invention that hasenhanced agronomic traits. Any soybean plant can be used in the practiceof the methods of this invention for producing a transgenic chromosome,seed or plant having an enhanced agronomic trait.

The non-natural transgenic chromosomes of the invention can be preparedby inserting a recombinant DNA construct of this invention into anatural soybean chromosome or into an already transgenic soybeanchromosome. Alternatively, the recombinant DNA that is transcribed to anRNA molecule of this invention can be placed on an artificial chromosomethat is embedded in the nucleus of soybean plant cells using methodsdisclosed in Patent Application Publication US2009/0156793A1,US2008/0256669A1, and US2009/0209749 A1, which are incorporated hereinby reference.

Recombinant DNA constructs useful in this invention include a promoteroperable in soybean cells and operably linked to DNA that is transcribedto an RNA molecule designed to inhibit the function of a mature miR171miRNA. In some embodiments the recombinant DNA constructs of thisinvention include DNA that is transcribed to multiple RNA moleculesdesigned to inhibit more than one miRNA in the miR171 miRNA family ormore than one gene having a miR171 miRNA recognition site, e. g., wheresegments of DNA that are transcribed to the multiple RNA molecules arearranged in tandem and expressed by action of a single promoter orseparate promoters. Various promoters useful for expressing recombinantDNA constructs of this invention, include, but are not limited to,tissue-specific promoters and ubiquitous constitutive promoters. Therecombinant DNA construct can also include other DNA, e. g., DNAencoding a transgene for expressing a protein or a selectable marker tofacilitate transformation or a gene suppression element. In arecombinant DNA construct that is designed to also transcribe RNA codingfor a protein or to non-coding RNA or both coding and non-coding RNAs,the DNA that is transcribed to an RNA molecule of this invention can belocated in an intron or after the polyadenylation signal, to permitnormal transcription of the other coding or non-coding DNA. A functionalRNA molecule of this invention can be expressed as a separate RNAmolecule, and a functional RNA molecule of this invention can also beembedded in other RNA, e. g., an RNA molecule of this invention can beembedded in the 3′-untranslated region of a protein-coding transcript.In one embodiment, a nucleotide spacer varying in size (e. g., 60nucleotides or more than 60 nucleotides) can be inserted between thestop codon of a coding sequence and the DNA that transcribes to an RNAmolecule of this invention; such a spacer sequence can increase theefficiency of the RNA molecule of this invention in inhibiting a maturemiR171 miRNA. Useful chromosomes of this invention can also be obtainedfrom transgenic soybean plants of this invention, e. g., for use inpreparing other soybean plants by breeding techniques for transferringDNA from a chromosome in one plant to a chromosome in another.

A miRNA can be described by providing the nucleotide sequence of themature miRNA, or of a miRNA precursor to the mature miRNA (such as theprimary transcript of a miRNA gene or pri-miRNA), or of an intermediatein miRNA biogenesis such as a pre-miRNA, or of a cognate DNA (e. g., theDNA sequence encoding the mature miRNA, or genomic DNA of a MIR genethat is transcribed and processed to the mature miRNA, or DNA encoding anaturally occurring, e. g., endogenous, or an artificial miRNA precursorRNA molecule that is processed to the mature miRNA). Table 1 providesRNA sequences of mature miR171 miRNAs and the corresponding precursormiR171 miRNA that were identified from the publicly available miRBasedatabase (mirbase.org). Additional miR171 genes and mature miRNAs andtheir targets arc also described in Patent Application PublicationsUS2005/0120415A1 and US2005/144669A1, which are incorporated byreference herein. The miR171 miRNA precursor RNAs are processed in thevarious plant species to the mature miR171 miRNAs.

With reference to Table 1, in column 1 there are sequence identifiersfor miR171 RNA precursor sequences in the sequence listing (SEQ ID NOS:1-16 for miR171 precursors), as well as the corresponding miRBaseAccession Number Identifier (e. g., MI0000214) and organism identifier(e. g., athMIR171a) which includes a three-letter prefix indicating thespecies in which the mature miRNA was first identified. Column 2 showsthe nucleotide sequence of the miR171 precursor. Column 3 is thesequence identifier (SEQ ID NOS: 17-32) for the mature miR171 miRNA.Column 4 shows the RNA sequence of the mature miR171 miRNA and thenucleotides in the precursor RNA from which the mature miR171 miRNAswere derived. The three letter prefix in the organism identifier isshown in parentheses following the species name: Arabidopsis thaliana(ath), Otyza sativa (osa), Zea mays (zma), Sorghum bicolor (sbi),Medicago truncatula (mtr), Brassica napus (bna), Triticum aestivum(tae), Glycine max (gma), Solanum lycopersicum (sly), Brassica rapa(bra), Brassica oleracea (bol).

The nucleotide sequences of mature miR171 miRNAs, SEQ ID NOS: 17-32(Table 1) and SEQ ID NOS: 33-92 (Table 2) are used to design arecombinant DNA molecule that can be stably integrated into a chromosomeof a soybean plant cell and be transcribed in that cell to an RNAmolecule that hybridizes to a mature miR171 miRNA to form acleavage-resistant duplex to reduce the function of the mature miR171miRNA. The mature miR171 miRNAs for many of the plant species have amiR171 consensus sequence of UGAUUGAGCCGCGCCAAUAUC (SEQ ID NO: 91) or ofUUGAGCCGNGCCAAUAUCACN (SEQ ID NO: 92) where the typical cleavage site ofthe mature miR171 miRNA is indicated by the underscored nucleotides apositions 10 and 11.

TABLE 1 miR171 precursor SEQ ID NO:, Mature miRBase miR171 accession(nucleotide number and Mature positions organism miR171 miR171 in miR171identifiers precursor sequence SEQ ID NO: precursor) 1AUGAGAGAGUCCCUUUGAUAUUGGCCU 17  (88-108) MI0000214GGUUCACUCAGAUCUUACCUGACCACA UGAUUGAGCCGCG athMIR171aCACGUAGAUAUACAUUAUUCUCUCUAG CCAAUAUC AUUAUCUGAUUGAGCCGCGCCAAUAUCUCAGUACUCUCUCGU 2 UGCAAGGUAACGCGAGAUAUUAGUGCG 18 (78-98) MI0000989GUUCAAUCAAAUAGUCGUCCUCUUAAC UUGAGCCGUGCCA ath-MIR171bUCAUGGAGAACGGUGUUGUUCGAUUGA AUAUCACG GCCGUGCCAAUAUCACGCGGUAAACCAAAAAUGGCA 3 GCGACGACGGGAUAUUGGGGCGGUUCA 19 (70-90) MI0001133AUCAGAAAGCUUGUGCUCCGGAAGCGA UGAUUGAGCCGUG osa-miR171bGGAGCUCUACUCUUUUGAUUGAGCCGU CCAAUAUC GCCAAUAUCACGUCGCAUC 4GACAUGGCAUGGUAUUGACUUGGCUCA 20 (59-79) MI0001138UCUCAGCAACAGCAAACUGCAUGCAGC GAGGUGAGCCGAG osa-MIR171gGCUGGAGGUGAGCCGAGCCAAUAUCAC CCAAUAUC UUCAUGUC 5UAAAAAGAGGUAUUGGCGUGCCUCAAU 21  (88-108) MI0001155CCGAAGGCAUGGCUGAUUACAGGCACC GGAUUGAGCCGCG osa-MIR171iUCGACCGAUCUAGCGCAUGCAGCCAUG UCAAUAUC UUUCUUGGAUUGAGCCGCGUCAAUAUCUCUCCUUGCUUC 6 AGGAGGAAGAAGACGACAUGGCGUGGU 22  (85-105) MI0001570AUUGUUUCGGCUCAUGUCCUUCUUGCU GUGAGCCGAACCA sbi-MIR171eUCGAGUCUGUCGUCGGAUUUUGGAUGU AUAUCACU GAUGUGAGCCGAACCAAUAUCACUCAUGUAUUCUUCAUUCUGA 7 UGAGAGAAUAAGACGACAUGGCGUGAU 23 (72-92) MI0001854GUUGUUUCGGCUCAUGCAUAUCCUUCU UGAGCCGUGCCAA sbi-miR171fUGAGUGUAUCAUCAGGAAAGAGGCGAU UAUCACGA GAGCCGAACCAAUAUCACUCAUGUAUUCUUCAUUCAUA 8 UGAAUUCCCCUCCGCUUUUUGAUGUUG 24 (75-95) MI0001753GCUUGUCUCAAUCAAAUCAAAGUUCUU UGAUUGAGUCGUG mtr-MIR171GAAAUUUGAGUUCUUUAGUCUGAUUGA CCAAUAUC GUCGUGCCAAUAUCAUAUUAAGCGAUA AAAGUC9 CGGGAUAUUGGCGCGGUUCAAUCAGAA 25 (65-84) MI0001492AGCUUGCGCUCCAGGCCCGAGGGGCUC UUGAGCCGUGCCA zma-miR171bCACUCUUUGAUUGAGCCGUGCCAAUAU AUAUCAC CACG 10 GGGGAAUCGAAAACCUACGGGAUAUUG26 (79-99) MI0001835 GUGCGGUUCAAUCAGAAAGCUUGCGCU UGACUGAGCCGUGzma-miR171c CCAAAGCCCAGGGGCUCCACUCUUUGA CCAAUAUCCUGAGCCGUGCCAAUAUCACGUCCUCG 11 UUGGUUGUUGGCUGAGAGAGUGCGAUG 27 (118-138)MI0001793 UUGGCAUGGCUCAAUCAACUCGCCGGC UUGAGCCGUGCCA zma-MIR171fCGCGGGUGGCUUAUAGCUUAAUUCUGC AUAUCACA GCAUUCGAUCGAGGUGCGGGCGCAGUG 12UGGUCAAGCGAGAUAUUAGUGCGGUUC 28 (65-85) MI0006450AAUCAAAUAGUCUCACUCUUAGUUGAU UUGAGCCGUGCCA bna-MTR171aAGAGAUUGAUUUUGUUCGAUUGAGCCG AUAUCACG UGCCAAUAUCACGCAUAUAACCA 13GGUAACGCGAGAUAUUAGUGCGGUUCA 29 (22-42) MI0006451AUCAAAUAGUCGUGUUCUCACUUGAUA UAUUGGUGCGGUU bna-miR171bGAGAUCGGUUUUGUUCGAUUGAGCCGU CAAUGAGA GCCAAUAUCACGCGUCAACC 14GCGAGAUAUUAGUGCGGUUCAAUCAAA 30 (75-94) MI0006452UAGUCGUACUCUUAGCUAUUAGAGAUC UUGAGCCGCGCCA bna-MIR171cGGUUUUGUUCGAUUGAGCCGUGCCAAU AUAUCAC AUCACGC 15GAUAUUGGCCUGGUUCACUCAGAUUAC 31 (62-82) MI0005771ACACGUACUAUAUGCAUUCUCUUAGUU CGAGCCGAAUCAA bna-MIR171gAUCUGAUUGAGCCGCGCCAAUAUCUC UAUCACUC 16 UGGAAUGGUCACUAUGAUGUUGGCUCG 32 (87-107) MI0006175 ACUCACUCAGACCACGCCUGCCGGCCG UGAUUGAGCCGUG tae-MIR171GCCGUAGCCAUGCAUCUGCAUGCGGUG CCAAUAUC GUGGCUCUGAUUGAGCCGUGCCAAUAU

With reference to Table 2 there is listed the sequences of the maturemiR171 miRNAs from several plant species to illustrate both the highconservation among miRNAs in a given miRNA family and the sequencevariability of mature miRNAs within a family. The mature miR171 miRNAfamily members were selected from sequences of small RNAs isolated fromthe indicated plant species. In Table 2, column 1 provides a referenceto a sequence identifier (SEQ ID NO:) in the sequence listing (SEQ IDNO: 33-92), column 2 provides the nucleotide sequence of the maturemiR171 miRNA, column 3 provides the nucleotide length for the maturemiR171 miRNA, and column 4 provides the specific miR171 name (e. g.,ath-miR171a), which includes a three-letter prefix for the organism fromwhich the mature miRNA was first identified: Arabidopsis thaliana (ath),Oryza sativa (osa), Zea mays (zina), Medicago truncatula (mtr), Brassicanapus (bna), Vitis vinifera (vvi), Populus trichocarpa (ptc) andSelaginella rnoellendorffii (smo).

TABLE 2 SEQ Length ID (nucle- NO: Mature naiP171 miRNA otides)annotation 33 UGAUUGAGCCGGGCCAAUAUC 21 ath-miR171a 34CAUUGAGCCGUGCCAAUAUCA 24 ath-miR171b CGC 35 AUUGAGCCGUGUCAAUAUC 19ath-miR171 36 UGAUUGAGCCGUGUCAAUAUC 21 ath-miR171 37UGAUUGAGCCGUGACAAUAUC 21 ath-miR170 38 UGAUUGAGCCGCGCCAAUAU 20zma miR171a 39 UGACUGAGCCGUGCCAAUAUC 21 zma-miR171c 40UGAUUGAGCCGUGCCGAUAUC 21 osa-miR171b 41 AUUGAGCCGUGUCAAUAUC 19osa-miR171b 42 UGAUUUAGCCGUGCCAAUAUC 21 osamiR171b 43UGAUUGAGCCGUGCCAAUA 19 osamiR171b 44 UGAUUGAACCGUGCCAAUAUC 21 osamiR171b45 UGAUUAAGCCGUGCCAAUAUC 21 osa-miR171b 46 UGAUUGAGCCGUUGCCAAUAU 23osa-miR171b UC 47 UGAUUGAACCGUGCCAAUAUC 21 osa-miR171b 48UGAUUGAGCCGUUCCAAUAUC 21 osa-miR171b 49 UGAUUGAGACGUGCCAAUAUC 21osa-miR171b 50 UGAUUGAGCCGUGCCAAUACC 21 osa-miR171b 51UGAUUGAGCCGUGCAAAUAUC 21 osa-miR171b 52 UGAUUAAGCCGUGCCAAUAUC 21osamiR171b 53 UGAUUGAGCCGUCCCAAUAUC 21 osamiR171b 54UGAUUGAGCCGUGCUAAUAUC 21 osamiR171b 55 UGAUUGAGCAGUGCCAAUAUC 21osa-miR171b 56 UGAUUGAUCCGUGCCAAUAUC 21 osa-miR171b 57UGAUAGAGCCGUGCCAAUAUC 21 osa-miR171b 58 UGAUUGAGCCGUGCCUAUAUC 21osa-miR171b 59 UGAUUGAGCUGUGCCAAUAUC 21 osa-miR171b 60UGAUUGAGCCGUGCCAAUAUA 21 osa-miR171b 61 UGAUUGAGCCGUGCCAGUAUC 21osa-miR171b 62 UGAUUGAGCCGUGCCCAUAUC 21 osa-miR171b 63UGAUUGAGCCGUGCCAAUAUC 24 osa-miR171b UGG 64 CGAUUGAGCCGUGCCAAUAUC 21osa-miR171b 65 UUAUUGAGCCGUGCCAAUAUC 21 osa-miR171b 66UGAUUGAGCCGUGCCGATA 19 osa-miR171b 67 UGAUUGAGCCGUGCCAAUAUU 21osa-miR171b 68 CAUUGAGCCGUGCCAAUAUCA 21 osa-miR171b 69UGAUUGAGCCGUGCCAAUAUC 22 osa-miR171b C 70 UGAUUGAGCCGUGCCACUAUC 21osa-miR171b 71 AUCUGAUUGAGCCGUGCCAAU 24 osa-miR171b AUC 72UUGAUUGAGCCGUGCCAAUAU 22 osa-miR171b C 73 UCUGAUUGAGCCGUGCCAAUA 23osa-miR171b UC 74 CUGAUUGAGCCGUGCCAAUAU 22 osa-miR171b C 75UGAUUGAGCCGUGCCAAUCUC 21 osa-miR171b 76 UGAUUGAGCCGUGCCAAUAUU 23osa-miR171b UU 77 UGAUUGAGCCGUGCCAAUUUC 21 osa-miR171b 78UGCUUGAGCCGUGCCAAUAUC 21 osa-miR171b 79 UGAUUGAGUCGUGCCAAUAUC 21mtr-miR171b 80 UGAUUGAGUCGUGCCAAUAUC 21 mtr-miR171 81UGAUUGAUCCGCGCCAAUAUC 21 bna-miR171 U 82 UGAUUGAGCCGUGCCAAUAUU 22bna-miR171g U 83 UGAUUGAGCCGUGCCAAUAUC 22 bna-miR171g U 84UUUGAUUGAGCCGCGUCAAUA 21 vvi-MIR171b 85 AUUGAGCCGCGUCAAUAUC 19vvi-miR171b 86 UGAGCCGCGCCAAUAUCACAU 21 ptc miR171a 87AGAUUGAGCCGCGCCAAUAUC 21 ptc-miR171c 88 UAGAUUGAGCCGUGCCAAUAU 22ptc-miR171c C 89 GGAUUGAGCCGUGCCAAUAUC 21 ptc-miR171k 90UUGAGCCGUGCCAAUAUCACU 21 smomiR171a 91 UGAUUGAGCCGCGCCAAUAUC 21consensus 92 UUGAGCCGNGCCAAUAUCACN 21 consensus

In one aspect of the invention an RNA molecule that hybridizes to andforms a cleavage-resistant duplex to reduce the function of a maturemiR171 miRNA is designed to hybridize with at least one mature miR171miRNA across the cleavage site of the mature miR171 miRNA, but canhybridize along the full length of the mature miR171 miRNA or extendbeyond the 5′ and 3′ ends of the mature miR171 miRNA. The RNA moleculeis at least 11 nucleotides and typically between 19 and 26 contiguousRNA nucleotides or larger and is sufficiently complimentary to themature miR171 miRNA to form the cleavage-resistant duplex. Such RNAmolecules of this invention are not perfectly base-paired with themature miR171 miRNA at the cleavage site. The cleavage site is locatedwithin the mature miRNA typically located between nucleotides 10 and 11of the mature miRNA. In some embodiments, the mature miR171 miRNA has aconsensus RNA nucleotide sequence of UGAUUGAGCCGCGCCAAUAUC (SEQ ID NO:91) or of UUGAGCCGNGCCAAUAUCACN (SEQ ID NO: 92), where the sequence ofthe mature miR171 miRNA has up to 6 mismatches with the miR171 consensussequence with which it best aligns (either SEQ ID NO: 91 or SEQ ID NO:92) and includes up to 2 nucleotide additions or up to 2 nucleotidedeletions at the 5′ terminus, the 3′ terminus, or both the 5′ and 3′termini of the mature miR171 miRNA. In these embodiments, the cleavagesite of the mature miR171 miRNA is between nucleotides that correspondto the nucleotides at positions 10 and 11 of the miR171 consensussequences that best aligns with the nucleotide RNA sequence of themature miR171 miRNA, and the RNA molecule is not perfectly base-pairedwith the mature miR171 miRNA (a) at least at position 11 at the cleavagesite, (b) at least at positions 10 and 11 at the cleavage site, or (c)includes at least one insertion nucleotide between the nucleotides thatarc complementary to positions 10 and 11 at the cleavage site. In otherembodiments the RNA molecule includes at least three insertionnucleotides inserted between the nucleotides that are complementary topositions 10 and 11 at the cleavage site. Specific embodiments of theRNA molecule of this invention include an RNA molecule having an RNAnucleotide sequence selected from the group consisting of SEQ ID NO: 93through SEQ ID NO: 118.

Exemplary transcribed RNA molecules of the invention that hybridize to amature miR171 miRNA to form a cleavage-resistant duplex comprise an RNAnucleotide sequence of any of SEQ ID NOS: 93-118, i. e., a nucleotidesequence that is generally complementary to the nucleotide sequence ofthe target mature miR171 miRNA except at the cleavage site of the maturemiR171 miRNAs. With reference to FIG. 1 there is shown two structures oftranscribed RNA molecules that are effective in the practice of thisinvention and that can hybridize to a mature miR171 miRNA with athree-nucleotide insertion (“bulge”) corresponding to positions 10-11 atthe cleavage site of the mature miR171 miRNA (FIG. 1A) or with twomismatches (“mismatch”) corresponding to nucleotide positions at 10 and11 at the cleavage site of the mature miR171 miRNA (FIG. 1B). Sequencemodifications to the RNA molecules of this invention where themodification is at one or more nucleotides corresponding to thenucleotides at or near the mature miR171 miRNA cleavage site can affectthe degree of functional impairment of the mature miR171 miRNAs and areuseful for providing variability in the phenotype in the plant. Theinteractions between the mature miR171 miRNA and the RNA molecule ofthis invention can be varied by the number or type of mismatches betweenthe mature miR171 and the RNA molecule, e. g., one to six nucleotideinsertions (mismatches) can be used in the sequence of the RNA moleculeat nucleotide positions corresponding to the cleavage site of the maturemiR171 miRNA, thereby creating “bulges” of varying size between the RNAmolecule of this invention and the mature miR171 miRNA. For instance,miRNA function is less affected by a single mismatch at position 11 thanby a mismatch at both positions 10 and 11 than by an insertion of threenucleotides between positions 10 and 11. The ability to modify thedegree of inactivation provides a means to systematically titrate theendogenous miR171 miRNA activity for achieving a desired level of theregulation of miR171 target mRNAs.

Table 3 discloses the design of examples of RNA molecules that areuseful in the practice of this invention and which hybridize to and forma cleavage-resistant duplex with an endogenous mature miR171 miRNA. Inspecific embodiments the RNA molecule of this invention can have the RNAnucleotide sequence of any of SEQ ID NOS: 93-118, as referenced in Table3. With reference to Table 3, column 1 provides a reference to asequence (“SEQ ID NO:”) in the sequence listing (SEQ ID NOS: 93-118),column 2 shows the nucleotide sequence of an RNA molecule designed tohybridize to miR171 miRNA to form a cleavage-resistant duplex, column 3shows the sequence identifiers (“SEQ ID NOS:”) for the mature miR171miRNA (shown above in the table cell) and the RNA molecule thathybridizes to the mature miR171 miRNA (shown below in the table cell),column 4 shows an alignment between the mature miR171 miRNA (above) in a3′ to 5′ direction and the nucleotides of miR171 RNA molecule thathybridized (below) in a 5′ to 3′ direction.

TABLE 3 Sequences Alignment between for miR171 RNA mature miR171 miRNAmolecule that (3′ to 5′ direction) SEQ hybridizes SEQ and sequence of IDto mature ID miR171 RNA molecule NO: miR171 miRNA NO: (5′ to 3′direction)  93 GAUAUUGGCGCAU  17 CUAUAACCGCG---CCGAGUUAGU AGGCUCAAUCA 93 GAUAUUGGCGCAUAGGCUCAAUCA  94 GAUAUUGGCGUCG  17 CUAUAACCGC--CGAGUUAGUCUCAAUCA  94 GAUAUUGGCGUCGCUCAAUCA  95 AAUAUUGGUGUCA  17CUAUAACCGCGC---CGAGUUAGU AAGCUCAAUCA  95 AAUAUUGGUGUCAAAGCUCAAUCA  96GGUGAUAUUGGCU  18 GCACUAUAACCG---UGCCGAGUU ACACGGCUCAA  96GGUGAUAUUGGCUACACGGCUCAA  97 AAAUAUUGGUGUC  81 UCUAUAACCGCGC---CGAGUUAGUAAAGCUCAAUCA  97 AAAUAUUGGUGUCAAAGCUCAAUCA  98 AGAUUUUUGUGUG  81UCUAUAACCGCGC---CGAGUUAGU CAGGCUCAAUCA  98 AGAUUUUUGUGUGCAGGCUCAAUCA  99UUUGUUGGCACAA  19 CUAUAACCGUGC---CGAGUUAGU GUGCUCAAUCA  99UUUGUUGGCACAAGUGCUCAAUCA 100 GAUAUUGGCGCAA  19 CUAUAACCGUG----CCGAGUUAGUUAGGCUCAAUCA 100 GAUAUUGGCGCAAUAGGCUCAAUCA 101 GAUAUUGACGUGG  19CUAUAACCG--CCGAGUUAGU CUCAAUCA 101 GAUAUUGACGUGGCUCAAUCA 102GAUAUUAGUGUGG  19 CUAUAACC---CCGAGUUAGU CUCAAUCA 102GAUAUUAGUGUGGCUCAAUCA 103 GGGCUUGGCUUUC  20 CUAUAACCGAG---CCGAGUGGAGUGGCUCACCUC 103 GGGCUUGGCUUUCUGGCUCACCUC 104 GAUAAUUGUUAUG  20CUAUAACCGA--CGAGUGGAG CUCACCUC 104 GAUAAUUGUUAUGCUCACCUC 105CGUAGUGGCUGGG  20 CUAUAACCGA-CCGAGUGGAG CUCACCUC 105CGUAGUGGCUGGGCUCACCUC 106 GAUGUUGACACAC  21 CUAUAACUGCG---CCGAGUUAGGCGGCUCAAUCC 106 GAUGUUGACACACCGGCUCAAUCC 107 GAUAUAGCUGUGC  21CUAUAACUGCGC---CGAGUUAGG CUGCUCAAUCC 107 GAUAUAGCUGUGCCUGCUCAAUCC 108GAUGUUGGCACUC  21 CUAUAACUGCGC---CGAGUUAGG CUGCUCAAUCC 108GAUGUUGGCACUCCUGCUCAAUCC 109 AUAUUGGUGUCAA  38 UAUAACCGCGC---CGAGUUAGUAGCUCAAUCA 109 AUAUUGGUGUCAAAGCUCAAUCA 110 GUGAUAUUGGCUA  25CACUAUAACCG---UGCCGAGUU CACGGCUCAA 110 GUGAUAUUGGCUACACGGCUCAA 111GAAGUAUUGGCCA  25 CACUAUAACCG---UGCCGAGUU GACGGCUCAA 111GAAGUAUUGGCCAGACGGCUCAA 112 UUGAGGUUGGGCU  25 CACUAUAACC---GUGCCGAGUUCGCGGCUCAA 112 UUGAGGUUGGGCUCGCGGCUCAA 113 GAAAUUUGUACAU  26CUAUAACCGUG---CCGAGUCAGU AGGCUCAGUCA 113 GAAAUUUGUACAUAGGCUCAGUCA 114GGUGAUAUUGGCU  27 ACACUAUAACCG---UGCCGAGUU ACACGGCUCAA 114GGUGAUAUUGGCUACACGGCUCAA 115 GAUGUUGUCACGC  24 CUAUAACCGUGC---UGAGUUAGUACACUCAAUCA 115 GAUGUUGUCACGCACACUCAAUCA 116 GUGUGUUUUUGGG  86UACACUAUAACC---GCGCCGAGU CGCGCGGCUCA 116 GUGUGUUUUUGGGCGCGCGGCUCA 117GGUGUUGCCGCCG  87 CUAUAACCGCG---CCGAGUUAGA CGGCUCAAUCU 117GGUGUUGCCGCCGCGGCUCAAUCU 118 UAUGUUUGCGUAU  89 CUAUAACCGCG---CCGAGUUAGGGGGCUCAAUCC 118 UAUGUUUGCGUAUGGGCUCAAUCC

Another aspect of the invention provides RNA molecules that hybridize toa transcript of a target gene having a recognition site for a maturemiR171 miRNA, wherein the recognition site includes nucleotidescomplementary to nucleotides of the mature miR171 miRNA, to form acleavage-resistant duplex that reduces the function of the mature miR171miRNA. Such cleavage resistance is believed to be resistance to cleavageby an RNase III ribonuclease within or in the vicinity of the duplex orhybridized segment that is formed by binding of an RNA molecule of thisinvention to a mature mir171 miRNA recognition site in the transcript ofa gene targeted for enhanced expression. The specific binding of a RNAmolecule of this invention to of the transcript of a miR171miRNA-regulated target gene occurs within or in the vicinity of themiR171 miRNA recognition site found in that transcript in a manner thatreduces or prevents miR171 miRNA-mediated cleavage of the transcript bycompeting with the mature miR171 miRNA for binding to the recognitionsite and thus imparting to the transcript resistance to cleavage, e.g.,by an RNase III ribonuclease. In some embodiments the duplex orhybridized segment formed between the RNA molecule of this invention andthe target gene transcript extends over the full miR171 miRNArecognition site. In other embodiments the duplex is formed partiallyover the recognition site and partially over other RNA in the targetgene transcript (e. g., partially over nucleotides in the transcriptthat are adjacent to the recognition site). In other embodiments theduplex does not form within the recognition site but only within thetarget gene transcript sufficiently close to the recognition site tointerfere with binding by the miR171 miRNA. Thus, the RNA molecules ofthis invention are useful for enhancing the expression of one or moretarget genes having miR171 recognition sites.

In one embodiment, the general design of an RNA molecule that hybridizesto a transcript of a target gene having a recognition site for a maturemiR171 miRNA includes an RNA sequence that is essentially identical tothe RNA sequence of a mature miR171 miRNA except in the region of thecleavage site, e. g., with mismatches, insertions or deletions in theregion of the cleavage site. The RNA molecule can extend beyond therecognition site in either the 5′ or the 3′ direction or in bothdirections. Alternatively, the design of an RNA molecule that hybridizesto a transcript of a target gene having a recognition site for a maturemiR171 miRNA includes nucleotides that hybridize to part of therecognition site, including the cleavage site (with mismatches,insertions or deletions) or not including the cleavage site, i. e.,extending from the border of the cleavage site into the gene transcript.Such an RNA molecule typically forms a duplex with at least 6 to 10 basepairs in the miR171 miRNA recognition site. In still other embodiments,the RNA molecule optionally includes additional nucleotides that are notbase-paired to the RNA transcript of the targeted gene. In specificaspects of the invention the chromosome of this invention is designed tohave DNA that is transcribed to an RNA molecule that hybridizes to andforms a cleavage-resistant duplex with a transcript of a target genehaving a recognition site for a mature miR171 miRNA, wherein thecleavage resistant duplex includes (a) at least one mismatch between theRNA molecule and the miR171 miRNA recognition site corresponding topositions 9, 10, 11 or 12 (in 3′ to 5′ direction) of the mature miR171miRNA, or (b) at least one insertion or deletion in the RNA moleculecorresponding to positions 10, 11 or 12 (in 3′ to 5′ direction) of themature miR171 miRNA, or (c) a mismatch corresponding to the 3′ end ofthe recognition site where the 5′ nucleotide of a miR171 miRNA istypically a U, thus the RNA molecule can have a C, G, or A at theposition corresponding to the 3′ end of the recognition site. Additionalmethods on how to make and use an RNA molecule that under physiologicalconditions in a plant cell hybridizes to and forms a cleavage-resistantduplex with a transcript of a target gene having a recognition site fora mature miRNA are disclosed in Patent Application PublicationPCT/US2009/49392, which is incorporated herein by reference.

Exemplary RNA molecules that form cleavage-resistant duplexes with atranscript of a target gene having a recognition site for a maturemiR171 miRNA include the molecules having the RNA nucleotide sequence ofSEQ ID NO:119 to SEQ ID NO:143, more particularly illustrated in Table4. For example, the RNA molecule with the nucleotide sequence of SEQ IDNO: 119 is designed to reduce or prevent the function of at least oneendogenous mature miR171 miRNA derived from nucleotide positions 88-108from the miR171 miRNA precursor sequence from Arabidopsis miR171a (SEQID NO: 1) which corresponds to the mature miR171 miRNA (SEQ ID NO: 17).More specifically the RNA molecule represented by SEQ ID NO:119 hasmismatching nucleotides CG indicated in bold lower case (cg) as comparedto nucleotides GC at positions 11 and 12 in the mature miR171 miRNA.Table 1 illustrates various miR171 miRNA precursor sequences and theircorresponding mature miR171 miRNAs, which can be used to design RNAmolecules of this invention that inhibit in a specific manner maturemiR171 miRNAs from cleaving their target transcripts. Table 4illustrates embodiments of these RNA molecules which include mismatches(SEQ ID NOS: 119-130) or deletions (SEQ ID NOS: 131-142) at nucleotidepositions 9-12. With reference to Table 4 there is listed the sequencesof the RNA molecules designed specifically to miR171a miRNAs targetgenes. In Table 4, column 1 provides a reference to a sequenceidentifier (SEQ ID NO:) in the sequence listing (SEQ ID NO: 119-143),and column 2 provides the nucleotide RNA sequence of the RNA moleculewhere lower case, bolded letters indicate a nucleotide mismatch anddashes indicate nucleotide deletions and Ns indicate nucleotides thatare complementary to the RNA transcript outside of the miR171 miRNArecognition site.

TABLE 4 SEQ RNA molecule designed to block ID NO:cleavage of miR171 target gene 119 UGAUUGAGCCcgGCCAAUAUC 120UGAUUGAGCCGCGCCAAUAUg 121 UGAUUGAGgCGCGCCAAUAUC 122UGAUUGAGCgGCGCCAAUAUC 123 UGAUUGAGCCcCGCCAAUAUC 124UGAUUGAGCCGgGCCAAUAUC 125 UGAUUGAGggGCGCCAAUAUC 126UGAUUGAGCcgCGCCAAUAUC 127 UGAUUGAGCCgcGCCAAUAUC 128UGAUUGAGggcCGCCAAUAUC 129 UGAUUGAGggcgGCCAAUAUC 130UGAUUGAG-CGCGCCAAUAUC 131 UGAUUGAGCCGCGCCAAUAUC 132UGAUUGAGC-GCGCCAAUAUC 133 UGAUUGAGCC-CGCCAAUAUC 134UGAUUGAGCCG-GCCAAUAUC 135 UGAUUGAG--GCGCCAAUAUC 136UGAUUGAGC--CGCCAAUAUC 137 UGAUUGAGCC--GCCAAUAUC 138UGAUUGAG---CGCCAAUAUC 139 UGAUUGAGC---GCCAAUAUC 140UGAUUGAG----GCCAAUAUC 141 GAGCCcgGCCAAUAUg 142 UGAUUGAGCCcgGCCAA 143NNNNUGAUUGAGCC

The RNA molecule that hybridizes to a mature miR171 miRNA or atranscript of a target gene having a recognition site for a maturemiR171 miRNA to form a cleavage-resistant duplex is produced byrecombinant DNA that is stably incorporated into a chromosome which canbe located in a non-natural transgenic soybean cell, plant, seed, orplant part or in industrial raw material(s) derived from non-natural,transgenic soybean crushed seeds or plant parts. The industrial rawmaterial including the non-natural transgenic chromosomes of thisinvention can be processed into food and feed products, biodiesels,epoxidized oils, saponified oils, lotions, lubricants, solvents,coatings, and resin products.

Aspects of the invention are provided by transgenic plants, seed andplant cells that are produced by a method including the steps of (a)producing non-natural transgenic soybean plant cells by introducing intoa chromosome in the genome of a soybean plant cell a recombinant DNAmolecule that is transcribed to an RNA molecule that hybridizes underphysiological conditions to form a cleavage-resistant duplex with amature miR171 miRNA or a transcript of a target gene having arecognition site for a mature miR171 miRNA, (b) regenerating anon-natural transgenic plant from the transgenic soybean plant cells,and optionally producing non-natural transgenic progeny soybean plants,and (c) screening the population of transgenic soybean plants to selecta non-natural transgenic soybean plant having an enhanced agronomictrait (compared to a control plant) imparted by the recombinant DNAmolecule. A “transgenic chromosome, cell or plant” means a chromosome,cell or plant that contains the recombinant DNA construct of thisinvention stably integrated into the chromosome or in the genome of thecell or plant, typically as a single copy and heritable in progenyplants, seeds and cells. A transformed plant cell and transgenic progenyresulting from transferring the stably integrated recombinant DNA intoother soybean plant lines by crossing or introgression.

A further aspect of the invention is a method to increase the number ofpods per node in a non-natural transgenic soybean plant by regulatingthe activity of endogenous mature miR171 miRNA (and thereby regulatingthe miR171 target genes) by expressing in a cell of the transgenicsoybean plant a recombinant DNA construct that is transcribed to an RNAmolecule that under physiological conditions in the cell hybridizes toand forms a cleavage-resistant duplex with a mature miR171 miRNAmolecule or a transcript of a target gene having a recognition site fora mature miR171 miRNA. The production of RNA molecules that hybridize toendogenous mature miR171 miRNAs or to a transcript of a target genehaving a recognition site for a mature miR171 miRNA in soybean plantcells reduces the miR171 activity against target messenger RNA (mRNA),e. g., of endogenous target genes of the mature miR171 miRNA. Theproduction of RNA molecules of this invention in soybean plant cellsenables the inactivation or at least reduction in function of at leastone endogenous mature miR171 miRNA and thus inhibits the mature miRNAfrom regulating its natural target mRNA proteins. The production of RNAmolecules of this invention provides increased activity ofmiR171-regulated proteins.

Soybean Transformation Methods

Methods for transforming plant cells with recombinant DNA are known inthe art. In particular, Agrobacterium tumefaciens-based planttransformation methods for stable introgression of recombinant DNAconstructs into soybean chromosomes are useful in the practice of stablyintegrating a recombinant DNA construct into a soybean chromosome toproduce a non-natural transgenic chromosome of this invention. Suchrecombinant DNA constructs include one or more expression cassettes eachincluding a promoter operably linked to DNA, e. g., DNA that transcribesto an RNA molecule that hybridizes to a mature miR171 miRNA.Agrobacterium-mediated transformation methods and materials forpreparing the transgenic chromosomes, cells, and plants of thisinvention are disclosed in U.S. Pat. Nos. 5,731,179; 5,824,877;7,002,058 and in Patent Application Publications US2005/0183170A1;US2003/110532A1 and US 2009/0138985A1, all of which are incorporatedherein by reference. The DNA to be integrated can be advantageouslyflanked by T-DNA border elements from an Agrobacterium tumefaciens tumorinducing plasmid. The recombinant DNA constructs including expressioncassettes (e. g., a promoter and DNA to be transcribed such as the DNAthat is transcribed to an RNA molecule of this invention and DNAencoding a selectable marker) that can be transferred into a plant celland can be present on one transformation vector in a bacterial strainbeing utilized for transformation. In another embodiment, the multiplerecombinant DNA constructs can be present on separate transformationvectors.

In the practice of transformation DNA is typically introduced into onlya small percentage of target plant cells. Selectable marker genes areused to provide an efficient system for identification of those cellsthat are stably transformed with a recombinant DNA molecule. Selectablemarkers confer resistance to a selective agent such as an antibiotic oran herbicide. A number of selectable marker genes are known in the artand can be used in the present invention. Selectable marker genesconferring tolerance to antibiotics like kanamycin and paromomycin(nptll), hygromycin B (aph IV), spectinomycin (aadA, U.S. PatentPublication 2009/0138985A1) and gentamycin (aac3 and aacC4) or toleranceto glyphosate (e. g., 5-enolpyruvylshikimate-3-phosphate synthase(EPSPS), U.S. Pat. No. 5,627,061; U.S. Pat. No. 5,633,435; U.S. Pat. No.6,040,497; U.S. Pat. No. 5,094,945), tolerance to sulfonyl herbicides(e. g., acetohydroxyacid synthase or acetolactate synthase conferringtolerance to acetolactate synthase inhibitors such as sulfonylurea,imidazolinone, triazolopyrimidine, pyrimidyloxybenzoates and phthalide;(U.S. Pat. Nos. 6,225,105; 5,767,366; 4,761,373; 5,633,437; 6,613,963;5,013,659; 5,141,870; 5,378,824; 5,605,011); tolerance to bialaphos orphosphinothricin or derivatives (e. g., phosphinothricinacetyltransferase (bar)) tolerance to phosphinothricin or glufosinate(U.S. Pat. Nos. 5,646,024; 5,561,236; 5,276,268; 5,637,489; 5,273,894);tolerance to dicamba (dicamba monooxygenase, Patent ApplicationPublications US2003/0115626A1), or tolerance to sethoxydim (modifiedacetyl-coenzyme A carboxylase for conferring tolerance tocyclohexanedione (sethoxydim)), and tolerance toaryloxyphenoxypropionate (haloxyfop, U.S. Pat. No. 6,414,222).

The promoters used in the expression cassettes of the recombinant DNA ofthis invention can include “enhancer” DNA that assists in elevatingexpression of the recombinant DNA. Enhancers are often found 5′ to thestart of transcription in a promoter that functions in eukaryotic cells,but can often be inserted upstream (5′) or downstream (3′) to the codingsequence. In some instances, these 5′ enhancing elements are introns.Such enhancers are known in the art. Useful enhancers are the 5′introns, for example, Arabidopsis actin 7 intron. Other particularlyuseful enhancers arc the 5′ introns of the rice actin 1 (U.S. Pat. No.5,641,876) and rice actin 2 genes, and the CaMV 35S enhancer (U.S. Pat.Nos. 5,359,142 and 5,196,525) or an octopine synthase enhancer (U.S.Pat. No. 5,290,924). The promoter can also be followed by non-translatedleader DNA derived from unrelated promoters as disclosed in U.S. Pat.No. 5,362,865. The promoter can also be non-translated leader DNAderived from unrelated promoters as disclosed in U.S. Pat. No.5,362,865. Non-translated leader DNA can include maize and petunia heatshock protein leaders (U.S. Pat. No. 5,362,865), plant virus coatprotein leaders, plant Rubisco leaders, GmHsp (U.S. Pat. No. 5,659,122),and Ph. DnaK (U.S. Pat. No. 5,362,865).

Expression cassettes of this invention can also include a DNA near the3′ end of the cassette that acts as a signal to terminate transcriptionfrom a heterologous nucleic acid and that directs polyadenylation of theresultant mRNA. These are commonly referred to as “3′-untranslatedregions” or “3′-non-coding sequences” or “3′-UTRs”. Expressioncassettes, e. g., for selectable markers can also include a transitpeptide for targeting a gene to a plant organelle, particularly to achloroplast, leucoplast or other plastid organelle. For descriptions ofthe use of chloroplast transit peptides see U.S. Pat. Nos. 5,188,642 and5,728,925.

The insertion of recombinant DNA into a soybean chromosome to producetransgenic soybean cells by Agrobacterium-mediated transformation can bepracticed using a plasmid vector with the genetic elements as shown inTable 5, where column 1 describes the function of the segment of theplasmid, column 2 provides a short description of a discrete geneticelement and column 3 provides a more detailed description of theelement. Transgenic soybean plants having the transgenic chromosome ofthis invention and grown to maturity are observed to have enhancedtraits as compared to a control plant and are used to produce transgenicseed of this invention. A transgenic event results from the randominsertion of recombinant DNA into a unique locus in a specificchromosome in a transgenic soybean cell. When each such uniquetransgenic cell is regenerated into a genetically unique transgenicsoybean plant, the plant and its progeny carrying the introducedrecombinant DNA in the same locus and chromosome are geneticallyidentical for the transgenic event. A person of ordinary skill in theart of plant transformation understands that multiple transgenic eventsare required to achieve an event with a desired phenotype and without anoff-type. For instance, recombinant DNA randomly inserted into achromosome has the possibility of disrupting the function of a nativegene to create an undesirable trait commonly called an “off-type”. Aselection method is designed to evaluate multiple transgenic plants(events) including the recombinant DNA sequence(s), for example multipleplants transformed with the DNA construct of the invention to producefrom 2 to 20 or more, often hundreds, of transgenic events. This is toprovide a population of transgenic plants that will allow selection of atransgenic plant exhibiting the target phenotype and without anoff-type. For commercial purposes, a single insertion of an intactrecombinant DNA construct is preferably in a single locus in achromosome. Transgenic soybean plants produced from transgenic cellsprovided by this invention demonstrate improved agronomic traits (e. g.,increased pods per node, increased number of internodes and nodes,decreased average internode length, or a twisted stem phenotype) ascompared to a control plant that does not contain or express therecombinant DNA construct.

TABLE 5 Function Genetic Element Description of Element AgrobacteriumAtu left border Agrobacterium left border for T-DNA transfer transfer ofT-DNA. marker expression Promoter Promoter from the Arabidopsis cassetteactin 7 gene 5′ UTR 5′ UTR of Arabidopsis Act7 gene Intron Intron fromthe Arabidopsis actin7 gene Transit Peptide Chloroplast transit peptideregion of Arabidopsis EPSPS Marker Synthetic DNA with divot preferredcodon usage for glyphosate resistant EPSPS. 3′ UTR A 3′ non-translatedregion of the nopaline synthase gene of Agrobacterium tumefaciens Tiplasmid which functions to direct polyadenylation of the mRNA. RNAmolecule Promoter Enhanced 35 S promoter from expression CaMV cassetteDNA DNA that is transcribed to an RNA molecule of SEQ ID NO: 91 thathybridizes to a mature miR171 miRNA. DNA DNA that is transcribed to anRNA molecule of SEQ ID NO: 119 that hybridizes to a in iR171 targetgene. 3′ UTR 3′ untranslated region from the fiber protein E6 gene ofsea- island cotton. Agrobacterium Atu right border Agrobacterium rightborder for T-DNA transfer transfer of T-DNA. Maintenance OR-Ec.oriV-RK2The vegetative origin of in E. coli replication from plasm id RK2.OR-Ec.ori-ColE1 The minimal origin of replication from the E. coliplasmid ColE 1. Marker Coding region for Tn7 adenylyltransferase(AAD(3″)) conferring spectinomycin and streptomycin resistance. 3′ UTR3′ UTR from the Tn7 adenylyltransferase (AAD(3″)) gene of E. coli.Promoter Promoter for Tn7 adenylyltransferase (AAD(3″)) CR-Ec.rop Codingregion for repressor of primer from the ColE1 plasmid. Expression ofthis gene product interferes with primer binding at the origin ofreplication, keeping plasmid copy number low.

The seeds of transgenic soybean plants can be harvested from fertiletransgenic plants and be used to grow progeny generations of transformedplants of this invention. In addition to direct transformation of aplant with a recombinant DNA, transgenic plants can be prepared bycrossing a first plant having a recombinant DNA with a second plantlacking the DNA. For example, recombinant DNA can be introduced into afirst plant line that is amenable to transformation to produce atransgenic plant which can be crossed with a second plant line tointrogress the recombinant DNA into the second plant line. A transgenicplant with recombinant DNA providing an enhanced trait, e. g., increasedpods per node, can be crossed with a transgenic plant line having otherrecombinant DNA that confers another trait, for example herbicideresistance or pest resistance, to produce progeny plants havingrecombinant DNA that confers both traits. Genetic markers associatedwith recombinant DNA are useful for producing transgenic progeny that ishomozygous for the desired recombinant DNA. Progeny plants carrying DNAfor both parental traits can be back crossed into a parent line multipletimes, for example usually 6 to 8 generations, to produce a progenyplant with substantially the same genotype as the one originaltransgenic parental line but having the recombinant DNA of the othertransgenic parental line. The term “progeny” denotes the offspring ofany generation of a parent plant prepared by the methods of thisinvention containing the recombinant DNA that produces an RNA moleculethat hybridizes to a mature miR171 miRNA.

Example 1

This example illustrates soybean transformation useful in producingtransgenic soybean chromosomes, cells, plants and plant parts of thisinvention. A plasmid as shown in Table 5 is used in procedures disclosedin Patent Application Publication US2009/0138985A1 to transfer therecombinant DNA for transcribing an RNA molecule of this invention intoa chromosome in a soybean cell. Multiple events of soybean cells withrecombinant DNA located in different loci in a transgenic soybeanchromosome are produced. Such non-natural transgenic soybean chromosomesinclude recombinant DNA that is transcribed to an RNA molecule thathybridizes under physiological conditions to a mature miR171 miRNA toform a cleavage-resistant duplex. Transgenic cells for each transgenicevent are regenerated into transgenic plants. With reference to FIG. 2transgenic soybean plants having the DNA construct that transcribes toan RNA molecules of SEQ ID NO: 93 exhibited high phenotypic penetranceand agronomic characteristics of increased pods per node, increasednumber of nodes and internodes, and a decreased distance betweeninternodes, as compared to a control non-transgenic soybean plant. Withreference to FIG. 3 there is shown in FIG. 3A, a transgenic soybeanplant having 5-6 pods on each of 3 separate nodes; in FIG. 3B, there isshown the rigid stalk and twisted stem phenotype exhibited by thetransgenic plant. Separate events of transgenic plants show a decreasein the internodal distance and increased pods per node per plant (FIG.4). With reference to FIG. 4 there is shown the enhanced traits insoybean plants from 4 separate transformation events that have areduction in internode length per plant (FIG. 4A) and an increase inrelative pod count per plant (FIG. 4B), as compared to a non-transgeniccontrol plant.

Example 2

This example illustrates further embodiments of the invention wheremultiple transgenic soybean chromosomes are prepared as described inExample 1 except that the DNA that is transcribed to an RNA molecule ofSEQ ID NO: 93 that hybridizes to a mature miR171 miRNA is replaced inseparate chromosomes by each of a DNA that is transcribed to one of theRNA molecules having an RNA nucleotide sequence of SEQ ID NOS: 94-118that is designed to hybridize to and form a cleavage-resistant duplexwith a mature mir171 miRNA. Multiple soybean transgenic events areproduced for each separate recombinant DNA construct transformed intosoybean cells which are regenerated into transgenic soybean plantshaving a chromosome of this invention. The transgenic soybean plants aregrown to maturity and screened to identify at least one event having theappropriate recombinant DNA construct (one of SEQ ID NOS: 93-118) andthat exhibits an enhanced phenotypic trait, e. g., an increased numberof pods per node compared to a control plant.

Example 3

This example illustrates embodiments of the invention where a transgenicsoybean chromosome is prepared as described in Example 1 except that theDNA that is transcribed to an RNA molecule of SEQ ID NO: 119 thathybridizes to a mature miR171 miRNA is replaced in separate chromosomesby each of a DNA that is transcribed to one of the RNA molecules havingan RNA nucleotide sequence of SEQ ID NOS: 119-143 that is designed tohybridize to and form a cleavage-resistant duplex with a transcript of atarget gene having a recognition site for a mature miR171 miRNA, i. e.,a miR171 miRNA recognition site on the transcript of a miR171-regulatedsoybean gene. Multiple soybean transgenic events are produced for eachseparate recombinant DNA construct transformed into soybean cells whichare regenerated into transgenic soybean plants having a chromosome ofthis invention. The transgenic soybean plants are grown to maturity andscreened to identify at least one event having the appropriaterecombinant DNA construct (one of SEQ ID NOS: 119-143) and that exhibitsan enhanced phenotypic trait, e. g., an increased number of pods pernode compared to a control plant.

Example 4

This example illustrates an aspect of the invention including deadtransgenic soybean plants having increased pods per node, where the podscontain viable transgenic soybean seeds having the non-naturaltransgenic soybean chromosomes of this invention. The transgenic soybeanplants produced in Examples 1, 2 and 3 are screened to identifytransgenic soybean plants having a chromosome of this invention. Suchplants are grown to maturity and exhibit increased pods as compared to anon-transgenic control soybean control plant. The mature soybean plantsare allowed to senesce into dead, non-viable plants. The viable seedcollected from the dead plants arc screened to identify homozygoustransgenic seeds which arc replanted to produce homozygous transgenicplants exhibiting increased pods per node. A quantity of the transgenicseed is also processed into a meal which can be used as an industrialraw material.

Example 5

This example illustrates still another embodiment of the inventionrelating to the utility of dead soybean plants of this invention. Viabletransgenic soybean seeds are harvested from the soybean plants ofExample 4 when the dead, senesced, leafless, non-natural, transgenicplants are aged to the point where the soybean seeds are air dried inthe mature bean pods to contain between 8 and 18 percent moisture. Theharvested, viable, transgenic soybean seeds have a transgenic chromosomeof this invention and are segregated into a population of seeds that aredesignated for planting and a population of seeds that are designatedfor crushing into a processed seed meal. Seeds that are designated forplanting are saved for the next planting season and planted to producetransgenic soybean plants of this invention. Seeds that are designatedfor crushing arc processed by milling to produce soybean meal havingresidual DNA in the form of chromosomes of this invention and to producesoybean oil that does not contain residual DNA and is processed intobiodiesel fuel.

What is claimed is:
 1. A non-natural transgenic chromosome in a soybeanplant cell, wherein the non-natural transgenic chromosome has arecombinant DNA construct comprising DNA that is transcribed to an RNAmolecule that under physiological conditions in a soybean plant cellhybridizes to and forms a cleavage-resistant duplex with either a maturemiR171 miRNA or a transcript of a target gene having a recognition sitefor a mature miR171 miRNA, wherein said recognition site comprisesnucleotides complementary to nucleotides of said mature miR171 miRNA,whereby the function of said mature miR171 mRNA is inhibited in saidsoybean plant cell, and wherein said soybean plant cell is in anon-natural, transgenic soybean plant having enhanced agronomiccharacteristics selected from a group consisting of increased pods pernode, increased number of internodes and nodes, decreased averageinternode length, and a twisted stem phenotype as compared to a control.2. The non-natural transgenic chromosome of claim 1, wherein the maturemiR171 miRNA has a consensus RNA nucleotide sequence ofUGAUUGAGCCGCGCCAAUAUC (SEQ ID NO: 91) or of UUGAGCCGNGCCAAUAUCACN (SEQID NO: 92), and wherein the sequence of the mature miR171miRNA has (a)up to 6 nucleotide mismatches with the one of the consensus RNAnucleotide sequences that best aligns with the sequence of the maturemiR171 miRNA and (b) up to 2 nucleotide additions or up to 2 nucleotidedeletions at the 5′ terminus, the 3′ terminus or both the 3′ and 5′termini of the mature miR171 miRNA.
 3. The non-natural transgenicchromosome of claim 1, wherein the mature miR171 miRNA has an RNAnucleotide sequence selected from the group consisting of SEQ ID NO: 17through SEQ ID NO:
 90. 4. The non-natural transgenic chromosome of claim2, wherein said RNA molecule hybridizes to and forms acleavage-resistant duplex with the mature miR171 miRNA.
 5. Thenon-natural transgenic chromosome of claim 4, wherein thecleavage-resistant duplex between the RNA molecule and the mature miR171miRNA includes at least one mismatch at the cleavage site of the maturemiR171 miRNA.
 6. The non-natural transgenic chromosome of claim 5,wherein the cleavage site of the mature miR171 miRNA is betweennucleotides that correspond to the nucleotides at positions 10 and 11 ofone of the consensus RNA nucleotide sequences of SEQ ID NO: 91 or SEQ IDNO: 92 that best aligns with the nucleotide RNA sequence of the maturemiR171 miRNA, and wherein the RNA molecule is not perfectly base-pairedwith the mature miR171 miRNA (a) at least a position 11 at the cleavagesite, (b) at least at positions 10 and 11 at the cleavage site, or (c)includes at least one insertion nucleotide between the nucleotides thatare complementary to positions 10 and 11 at the cleavage site.
 7. Thenon-natural transgenic chromosome of claim 6, wherein the RNA moleculeincludes at least three insertion nucleotides inserted between thenucleotides that are complementary to positions 10 and 11 at thecleavage site.
 8. The non-natural transgenic chromosome of claim 1,wherein said RNA molecule hybridizes to and forms a cleavage-resistantduplex with said transcript of a target gene at or in the vicinity ofsaid recognition site for a mature miR171 miRNA.
 9. The non-naturaltransgenic chromosome of claim 8, wherein the length of saidcleavage-resistant duplex comprises at least 10 base pairs.
 10. Thenon-natural transgenic chromosome of claim 9, wherein saidcleavage-resistant duplex is formed at least partially within therecognition site.
 11. The non-natural transgenic chromosome of claim 10,wherein said cleavage-resistant duplex comprises at least 6 base pairsin said recognition site.
 12. The non-natural transgenic chromosome ofclaim 8, wherein said cleavage-resistant duplex between said RNAmolecule and said transcript of a target gene includes at least onemismatch at the cleavage site of said mature miR171 miRNA.
 13. Thenon-natural transgenic chromosome of claim 8, wherein saidcleavage-resistant duplex comprises: a. at least one mismatch betweensaid RNA molecule and said recognition site corresponding to positions9, 10, 11 or 12 within said mature miR171 miRNA, or b. at least oneinsertion at a position in said RNA molecule corresponding to positions10-12 within said mature miR171 miRNA, or c. a mismatch at a positioncorresponding to the 3′ end of the recognition site.
 14. The non-naturaltransgenic chromosome of claim 1, wherein the RNA molecule has an RNAnucleotide sequence selected from the group consisting of SEQ ID NO: 93through SEQ ID NO: 118 and SEQ ID NO: 119 through SEQ ID NO:
 143. 15. Anindustrial raw material including non-natural transgenic chromosomes ofclaim
 1. 16. The industrial raw material of claim 14, whereinnon-natural transgenic chromosomes are in crushed soybean seeds.
 17. Anon-natural transgenic soybean plant having a non-natural transgenicchromosome of claim
 1. 18. A non-natural transgenic soybean seed havinga non-natural transgenic chromosome of claim
 1. 19. A non-naturaltransgenic soybean cell having a non-natural transgenic chromosome ofclaim
 1. 20. A dead non-natural transgenic soybean plant having maturebean pods containing non-natural, transgenic soybean seeds having anon-natural transgenic chromosome of claim
 1. 21. A method of increasingpods per node, number of internodes and nodes or a twisted stem in asoybean plant by providing in the soybean plant a non-natural transgenicchromosome of claim 1.